Rotary motor



Smmsmet 1 mb. IN ou d@ lmginall. Filed April 16, 19:55

P. E. GOOD ROTARY MOTOR Original Filed April 16v, 1935 8 sheetssheet 2 P. E. GOOD ROTARY MOTOR Dec. 27, 1938.

Original Filed April 16, 1935 8 Sheets-Sheet .'5

1 27,1938- REGOOD f 2,141,982

RoTAR YYYY 0R Dec. 27, 1938. P. E. GOOD 2,141,982

RRRRRRRRR OR Original Filed April 16, 1935 8 Sheets-Sheet 5 Dec. 27, 193s. E, GOOD 2,141,982

ROTARY MOTOR Ofiginal Filed April 16, 1935 8 Sheets-Sheet 6 P. E. GOOD ROTARY MOTOR Dec. 274, 1938.

Original Filed April 16, 1935 my J www P. E. GOOD ROTARY MOTOR` l Dec. 27, 1,938. i

Original Filed April 16, 1935 8 Sheets-Sheet 8 H?? .5* www Patented Dec. 27,- 1938 RoTARYMo'roR 5 Paul'E. Good, Riverton,

Application April 1s, 1935. serial No. 16,719

. Renewed May 21,-.1938 .s `:as claims. (C1. 121-61) This invention relates to fluid impeued rotary motors and more particularly to the production A of a small high speed motor of the type employed in operation of tube cleaners and the like in which 5 the motive uid is employed expansively.'

Important objects of the present invention are the modication of the type of motor illustrated in the patent to J. H. Watson. granted February 21, l

1911, No. 984.983 for Rotary engine, to enable the piston elements to be compactly arranged,to employ the gyroscopic forces engendered-infoperforces and for offsetting the tendencytmtwist on the part of the piston elements asa result'of 15 20 selves.

These and other objects 1 attainby the .con-

structionshown in the accompanying drawings wherein, for the purpose of illustration, I have shownV a preferred embodiment of my invention and wherein:

Fig. l is an enlarged longitudinal sectional View through a tube cleaner motor constructed in accordance with my invention;

Fig. 2 is an end elevation partially broken away of the rotor of Fig. l;

Fig. 3 is a sectional view through the stator of Fig. l, the construction lines indicating'the continuation of the grooves and the dotted lines B the path of movement of the inlet port;

Fig. 4 is a section on line 4 4 of Fig. 2;

Fig. 5 is a fragmentary sectional view showing an alternative form of pin mounting;

Fig. 6 shows a modification of the structure of Fig. l. in which the outer casing forms the rotor:

Fig. 7 is a modiecl construction employing two sets of pistons;

Fig. 8 is a section on line 8 8 of Fig. 7;

Fig. 9 is a side elevation of the rotor of Fig. 7;

Fig. 10 is a sectional view through the stator of 1.'. Fie. '7;

Figs. 11 and l2 are sections on lines II-Il and z lz of Fig. 9;

Figs. 13 and 14 are sections on lines I3I3 and I4I4 of Fig. l2;

i Fig. l5 is a development illustrating the stator and piston action in the construction shown in Figs. 7 in 14 inclusive:

Fig. 1G illustrates a modification of the struclurtl of Fig. 1 to enable use oi the device withincomprcssiblc fluids;

the pressure of iluid applied thereto and-.to fur-'- ther so arrange thepisto elements `-thatfric- Figs. 17 and 18- are characteristic front and rear end elevations of .the structures shown in Figs- 1 to 15 inclusive;

Fig, 19 is a detail sectional view illustrating a modiiledmounting of the pistons; 5

Fig..20 is an elevation of a modified form of rotor; l

Fig. 21 is ra fragmentary perspective view par- 'tlally broken-awayshowlng'the iiuid pressure de- 1 livery system and controls .of -shown-in-Fig.:9; and- 1; ation for the purpose ofosettingthe centrifugalV a structure such as rig. 2a is a diagrammatic view iimst'rao'ng'ole operation-ot centrifugaland gyroscopic .forces in motors constructed in accordance with my inventionm-.r-- f: :f f

Referring now'to the drawings. and more par- -.ticu1arly Figs. 1 Ato- 6.-,thereoi, the numerals I Il and II indicate relatively rotatable members which are concentric and have a rotating fit with one another.-A The members 4Il) and II are preferably enclosed within a suitable casing C. The outer member I0, which may. 8S will hereinafter more fully appear. comprise either a rotor or a stator, and in Figs. 1 to 5 comprises a stator, has a circumferential series of spiral grooves I2 formed therein, while the inner member II mountsa pair of rotatable piston elements I3 having lobes I4 to ilt and block the grooves as the pistons and members are rotated. The lobes I4 of the pistons may assume a variety of forms, and the grooves oi the member I0 will be correspondingly shaped, the grooves in any instance comprising the geometric figure described by a lobe projecting from the inner member when the inner and outer members and the pistons are rotated at constantly proportional speeds. In Figs. 1 to 6 and 16 the lobes are circular in form while in the remaining figures the lobes are shaped like gear teeth. these forms being generally preferred due to the ease of production. In Figs. 1 to 5, the outer member I0 comprises the stator and the inner member II a rotor to which the drive shaft I5 for cleaning tools or the like is secured. In Fig. 6 the inner member Ila comprises the stator. being secured to the iluid pressure supply lhose I 6, and the outer member Illa comprises the rotor and has the tool shaft I5a attached thereto.

The piston elements I3 are disposed within a diametral slot I1 and have corresponding faces thereof in overlapping sliding relation to one another, the extent Aof overlap employed varying with the relative diameters of the piston elements and of the inner member II. The construction shown in Figs. l to 5 employs piston elements having adiameter across opposed lobes slightly greater than the actual diameter of the rotor, thus enabling the use of lobes and grooves of considerable size. Since, however, it is desirable that the piston elements should-be capable of being housed within the confines of theslot, the mean over-al1 width of the piston elements is. accordingly, lessthan the diameter of the member I I.

Where vthe innert-member. piston elements are shapedlike gear teethori'some close approximation thereof, there is no necessity for anchoring these piston elements in position in the grooves, as centrifugal force will tend to urge the piston elements outwardly" and the form 'of the piston elements will prevent'any tendency to axial displacement thereof. Under such clrcvm' stances,`it is-possible to employisimply a spring= pressed button I8 (Fig. 8) or similar expedient for exerting a slight frictional contact with the walls of the groove to hold the piston element in position when the rotoris at rest. f l

When, however,the'piston lobes are of crcular form, it is obviously possible forlany given piston lobe to rotatein its groove-'andiunderlthese circumstances some -means for definitely locating the axes of the piston elements is desirable. Such' means may take a variety of forms, two forrnsf' being-herein illustrated-'ln Figs? 2,1- 4' and 5.' In Figs; 2 and 4,5the pistons are illustrated as mount-V ed upon'ipinsli which pins-comprise the stems' is the-rotor and the midway between the axes of these elements where the speed of rotation of the frictionally engaged faces-is substantially uniform and these faces are moving in the same direction.

In the lform of construction shown in Fig. 8, the contacting areas of the piston elements are all either in the zone of uniform speed or closely approximate this zone. In such a construction there is obviously little frictional contact between the-elements and there is, consequently, little wear as airesultof their contact with one another. while in the construction of Fig. 2 the same i conditions -obtain after a' short period of operation. Obviously, the piston elements of Fig. 2 V"couldbe -relieved as indicated by the dotted lines so that in initial operation this result would be obtained.'

Intakeport means are provided which comprise 'a port opening 28 formed in the inner member II. This intake port is so disposed that it traverses a circumferential band of the outer member including those 'ends of the grooves first engaged by the lobes of the piston-elements, the band being indicated by a' dotted line path B on Fig. 3 of the drawings.- When. by relative rotation of the members and the spiral arrangement of the grooves;` the port 28 isfaxially displaced so that it no longer'colncides'wlth the grooves, lthe intake is cut "oiI and subsequentpropulsion (to cause relative'rotation-of the members results solely 1:from expansion ofthe liluid Amedium which, after of pstons-20 mounted in cylinders 12I andnorw it is fullyexpandedfpasses'through exhaust port mallyspring-urgedliriwardlyby springs12 to ai position wher'ethese' "pins'will engage within-axial openingshfonedin --the pistons; 1- 'i-I'he opposite ends of the cylinders are placed in communication with" one end 'of the "innerf member-1I I through: ports 23, through whichfiluid" pressure may be introducedto withdraw for "seat 'the' pin. 'I Pref.'--`

erably, the fluid pressure'utilize'd" is in the forin"12v of a heavy'lubricantintroduced byV means of `a; grease= ga-orthe'llke. #11." ,4

In Fig. 5, .the piston mountlngscomprise simple pins 24 inserted through-the'wall 'of the member II and suitably 4locked inposition as indicated In any event, the mounting pins fit loosely, comprising not s'o much a"bearing for the piston element as a locating element therefor. In order that .the piston element may be spaced from a slot waliwhich it opposes, spacing means are provided which may either consist of a hub enlargement as at 26 in Fig. 2 or an inserted wear plate as at 2T in Fig. 5. From an inspection of Fig. 2, in whichthe arrows A indicate the direction of the application of pressure against the pistons. it will be obvious that with a loose locating pin there Will be tendency of the piston elements t0- rock upon these spacing elements 26 or 21 so that the inner portions -of the piston elements will tend to bear forcibly against one another,r While these piston elements are shown in solid lines as flatly engaging one another, it will be obvious that since the piston elements rotate fairly rapidly and are 'in pressure engagement with one another even though the piston elements be initially constructed so that they will flatly engage after a short period of operation, those portions of the faces where more rapid contact or relative movement occurs will become worn so that the faces no longer 'remain in Contact. At this time the piston elements of the type shown in Fig. 2 will have a form shown somewhat-.ex aggeratedly in dotted lines in Fig. 2. actual contact by the piston elements taking place at a point means 29 communicating 'with 'the' trailing ends fof thegroovesror those'endsthereof which are AAflastwengaged by agiven lobe'of the piston. 'As

:"shown in the drawings,this exhaust port means communicatesiwithA openlngsl in the casing C fi'preferablyescaping f vat that Y end of -the f casing through which the tool shaft I5 or I5a projects'.

. disclosed as comprising a longitudinally-extendingchannel 28a communicating at'one end with 'a cavity 28b formed'i'n the end of the rotor and to "which iluid pressure is delivered. In Figure 1 the delivery means to the cavity comprises a skeletonic gudgeon 28o carried by the adjacent end head of the casing C. This structure may, hcwever, be omitted as disclosed in Figures 6 and 16, and communication with the supply conduit established through a direct port.

It will be obvious that the greatest pressure exerted by the admitted fluid against the piston elements will be exerted during the admission period; that is to say, when the piston elements are in the position of the left-hand group of pistons illustrated'in Fig 7, f or at this time the lobe whichisflt engaging the' groove has the head pressure of the air applied thereto while that which is about to leave the groove has only expansion pressure applied thereto. This unbalance in pressures has a tendency to rotate the piston about an axis perpendicular to the axis of the piston so that the piston elements would tend to more forcibly engage one another at the point of initial contact thereof which is indicated by D in Fig. 1, the direction of rotation of the piston elements being indicated by the arrows of that ligure.

However, a second force, gyroscopic force, overcomes this tendency to a great extent. As is well known to those familiar with the art, any attempt to displace the axis of a rotating member in activen direction sets up forces operating at right angles to the applied force. Lending to displace the axis in a second direction. In the The supply to'the intake port 2821s at presentpresent instance, due to the direction of. attempted d-isplacement (byprotation ofthe rotor) and to the direction of rotation of the' piston elements, these gyroscopic forcesvtend to move the piston elements oppositely. `to, oneanother and oppositely to therexcess forces -applied by theY admission of uid. thus setting upa-tendency oi' the piston. elements to most ,forciblyiengage one;an-

1 other in the area where-'theiobes of;` the.p'iston elements separate., .whichz-is1 indicated: at .,E: in Fig. 1. ,'I'hus. afiorce; which: would bendetrimental. in. operation-Zand. a.;con'dition:.arising in operation which wouldrlkewise beidetrim'ental. are employed to offset ,one anotherby the .simple expedient ofv placing;the f piston felementsfln overlapping contacting:relations.r Furthermore; even though these piston-"elementsbeseparatedby an interveningxplatm.:forcesssetaups-in this-rr'nanner which .wouhi 4tend .to cause .fbodily-twistL-inethe structure still servef to-Ioffset :one-:another so that .the toolfasfaiwhole, mayfbe conveniently manipulatedf and be freedffrom'excessive internal strains. Attention ls'dire'cted tothe .factthat'by properly .z'forrningz;ther. grooves; the direction of rotation may be.Y made-such ithat" the? gyrosc'opic forces :mayfbe 'madeito `overcome th centrifugal eiort ofathe .-blades-and'-to substantially balance thesame so that frictional engagement between theedobesfrandethr grooveiwalls 'is materially duced. In Figureltlnashasbeen-isetfortliffth gyroscopic'zeiortriauses the`ilobes\-loi'=theipiston to pinch'zagainsts'oneffanotherfatf-Elf'hssurning that'theigyroscopiofforcefissmore `than'"siiilieient to..overcomei'thei=pre'ssure ofthflnooniing=tluid against'the lob'es ofthe-pistonandfthitndency to :twist che pistonfrom .this 'sourcelthus .enunnated. fthe :pinchingl of the pistons lagainst-#one another at E ,-willcau'sea tendency of' th Epist/:ons to .swing 'about 'the-point E' as `a. -pivot'softhatf the engagedriobesof thepismn will tend ign-separate from me walls ofthe groove. 1 This wmjnorfhovi ever, take place duetothe factf that' centrifugal effort tends tomove'the pistons? outwardly.' `By giving the pistonthe proper weight',th'dev'1ce when operated' at a given 'speed will be substantially frictionless in its co-aetion between the pistons `and groove walls. n I

In' the form of invention shown in Figs. 7 to 15 inclusive, -I have shown the'preferred arrangement employed with my 4invention 4Where ypower requirements and space necessitatethe use of more than one set of grooves and a corresponding number of groups of piston elements. In these gures. two sets of grooves and two sets of piston elements are employed and it will be noted that the grooves of the groups are oppositely spiraled with the result that the piston elements at corresponding sides of the inner member 3| will rotate in opposite directions to one anotheras indicated by the arrows. Therefore. forces set up by unbalanced fluid pressures on the piston elements and by gyroscopic effects will be completely balanced insofar as their effect upon the instrument as a whole is concerned. It will also be noted by an inspection of Fig. l0 and of the diagram forming Fig. l5 that the grooves of one series are staggered with relation to the grooves of the other so that the power exerted is very evenly distributed. In the diagram, F'. F"indicate the iiuid admission port bands of the groove groups G, G respectively, and with the direction of movement of the pistons relative to the grooves as indicated by the arrow in Figire l0, admission has just started in the grooves of group G while in the grooves of-group- Gf admissionhas substantially been completed- With furtherv multiplication of the numbersof,v groups of grooves and associated pistons,it will, of course, be possible'io secure .substantially uniform power application. These iigures further illustrate the applica tion of a governor foi-controlling iiuid admission to the grooves or. more strictly speaking.- [or controllingthe width of the admission band through 'which admission occurs totlie grooves. In.4 these figures the numeral 32-designates :fluid admissonchannelsiormed iir the inner member 3l and opening through -the u'all of the member' adjacent: the projecting ends oi each group oi' rotor elements -tlirough ports 33.- ;Ports .33 are -centrallylocated as regard'sjthe'groove `groups G and G' andepisuchrwidth that the circumferentialband traversed thereby laps the groove groups through a distance H, Fig; 15. Formed in each side of the body of the inner member is a' cylinder 34-at present shown as provided in the body by inserting-a suitable: cylindrical casing 35.;- The` walls Vof thesev cylinders have formed thereinportsxSSand 3],the ports 36- communicating` with-qthe. respective-passages 32 and. bcing. .located toward the zouten ends of the cylinders awhile the .-ports 31: communicate through Vportss-BB withxthe outeri surface offthe 'member 3 l; adjacent the frespective4 associated: piston Aelements:.;..'1wo:sets .ot ports 31 and 38-are provided for. eachcylindercandi the-ports. 38 are vaxially displaced fromrthei associated: -portfi'iy lying L on oppositezsidesithereof. as'may be-fvery readily determined by comparing'Figs413 and-'14.

.Ports 38# traverse 'ias 'circumferential 'band of the groove groups representedby the,V distance I in Fig 15, thus incre'asingith'e4 effective intake areatothe.widthoftheband F. Within each cylinderf34 isia -combined 'governor 'weight -and valve.'3$.'rthiselement -beingn'ormally maintained at the inner endof-the Icylinder'by adirectly' conltacting .coil vspring 40;' The element is suitably balanced for uidxpressures'as' indicated and upon outward movement will close the ports 31 to an extent dependent upon the position of the element 39 which is, in turn, dependent upon the centrifugal force generated in operation. If the speed becomes excessive. ports 31 are completely cut off so that only the ports 33 are effective in operation. Particular attention is d1- rected to the fact that the mechanism just described provides a governor mechanism in a structure of this character which is completely free of pivot pins or link connections. extremely important as it will be at once obvious that a device of this character constructed for use in. for example, a 1%" tube will have parts of such small size that any linkage or pin connections would mean provision in the structure of elements which would become :'noperaihf'n after a very short period of operation. Eiminntion of such elements can only be had through direct contact of the governor spring with #he combined weight and valve. i

In Fig. 16 I have illustrated a form oi construction suitable for use with'compressible nr incompressiblefluids. In such a construction it is manifestly possible to` form both the intake ports and exhaust ports in permanent communication with the grooves 4l as indicated at 42 and 43 respectively.

While-I have hereinbeiore referred lo the pis'.- tons as operatingr in direct contact. with one an other, it is obviously possible to employ a parri- This is A55 tion P therebetween, as suggested in Fig. 19; this partitionmay'either be stationary or float in the cavity, as desired.v f A In Fig.'20 I have illustrated a modified construction in which two sets of pistons are employed, to one of'which liuid pressure is constantly supplied' and the other of which has its supply ports controlled by a governor which closes at high speeds. This arrangement accomplishes the same result as the governor construction hereinbefore-described but has the additional advantagev of providing ample reserve power and yet permitting a minimum use of fluid pressure normal operation. A

Since'the constructions herein described ar obviously capable of considerable` modification and may, obviously, be employed in pumps Without in anymannerj departing from the spirit of my inventiomI do not Wish to be understood as limiting myself thereto except as hereinafter claimed.` I claim:

1. In a rotary motor or the like, a cylinder provided on 'its inner surface with a' circumferential series of spiral groves, a rotor in said cylindem-rotatable piston 'elements carried by the rotor and having lobes meshing with 'said grooves, the rotor havinga slot in which the body portions of`said piston elements are disposed, the inner portions of-said piston elements beingin `confronting@overlapping relation, said grooves being generated by the lobes ofthe piston elements when the piston elements lare positioned tointersect, the stator. and the piston elements randI rotor. arev rotated at constantly proportional speeds whereby the lobes fof the piston elementsblock said Vgrooves'from end to end during rotation of the rotor.V

2. In-a rotary ,motor or the like, -a. cylinder provided on its inner surface with acircumferential series of spiral grooves, a rotor :jin said cylinder, rotatable piston elements carried by thev rotor and having lobes meshing wth said grooves, the rotor having a slot in which the body portions of said piston elements are disposed, the inner portions of said piston elements being in confronting overlapping relation and having sliding engagement with one another, said grooves being generated by the lobes of the piston elements when the piston elements are positioned to intersect the stator and the piston elements and rotor are rotated at constantly proportional speeds whereby the lobes of the piston elements block said grooves from end to end during rotation of the rotor.

3. In a rotary motor or the like, a cylinder provided on its inner surface with a circumferential series of spiral grooves, a rotorl in said cylinder, rotatable piston elements carried by the rotor and having lobes meshing with said grooves, and blocking said grooves from end to end thereof during their movement therethrough the rotor having a slot in which the body portions of said piston elements are disposed. the inner portions of said piston elements being 1n confronting overlapping relation, and having sliding engagement with one another, the mutual contact, pressure region occurring between the axes of rotation of said piston elements.

4. In a rotary motor, a stator having a circumferential series of spiral grooves in the wall thereof, a rotor fitting the stator and haring a rotatable lobed piston element, the lobes of which coact with said grooves lo block the same, a supply port in the rotor traversing a circumferential band of the stator including those ends of the groovesfirst engaged by the lobes of said piston element, a second supply port traversing a second band including the intermediate portions of said grooves, a valve controlling said secondl port and movable radially of the rotor under the influence of. centrifugal 'force to close said second port and a spring opposing movement of'lsaid valve under the influence of centrifugal force and directly. engaging the valve.

5. In a rotary motor, a stator having two circumferential series of spiral grooves'arranged in parallel bands, thevgroovesof said series being oppositely spiraled, a rotor fitting the stator and having Vtwogroups of rotatable lobed piston elements the lobes of which coact with said grooves to block the same, a supply port yin the'rotor traversing a circumferential band of the stator including those ends of the Ygrooves oflboth'ser-ies first engaged by the-lobes of the associated pistonl elements,.other supply ports in 4 said rotor and each traversing a band of oneof saidY groove series immediately i.adjacent the band thereof traversedby the first-namedport, a valve-con trolling said second-named ports and movable radially of the rotor. under the influence-of centrifugal force;to close said second-named ports,

a spring opposing movement of said valve` under lthe influence of :centrifugal forcing-wandA means to exhaust fluid fromsaid grooves.-

. 6.1.Ina1rotary-:moton a stator-havingtwo circumferentialfseries of spiraLgrooves arranged in parallel .,bands, ,theggrooves'fofr said, series' being opposite1y-.spiraled, a rotor` fitting Vthez'stator and having 4two groups, of rotatable lobed piston elements, thelobes of which coactwith said grooves toblock the. same,l a supplyport vin the rotor traversing afcircumferential lband of the stator including thoseends of the grooves of both groups first engaged by the lobes-of thefassociatedplston elements, othersupplyfports in saidvrotor and eachtraversing a band of oneof said-groove series immediately adjacent 4the band thereof traversed bythe first-named port, a valve controlling saidsecond-named ports and movable radiallyy ofthe rotor under the influence of centrifugal force to close said second-named ports, a spring opposing movement of said valves under the influence of centrifugal force and directly engaging the valve, and means to exhaust fluid from said grooves.

7. In a rotary motor or the like, a stator having two circumferential series of spiral grooves arranged in parallel bands, the grooves of said series being oppositely spiraled, a rotor fitting the stator A and having two groups of rotatable lobed piston elements, the lobes of which coact with said grooves to block the same, a supply port in the rotor traversing a circumferential band of the stator including those ends of the grooves of both series first engaged by the lobes of the associated piston elements and means to exhaust fluid from the grooves.

8. In a rotary motor or the like, a statar having two circumferential series of spiral grooves arranged in parallel bands, the grooves of said series being oppositely spiraled, a rotor fitting the stator and having two groups of rotatable lobed piston elements, the lobes of which coact with said grooves to block the same, a supply port in the rotor traversing a circumferential band of the stator including those ends of the grooves of both series first engaged by the lobes of the associated piston elements, the grooves of the series to block the same, a supply port in the rotor traversing a circumferential band of the stator including those-ends of the grooves of both series first engaged by the lobes of the associated pisten elements, other supply ports in said rotor and each traversing a band of one of said grpove series immediately adjacent the band `thereof traversed by the first-named port, a valve controlling said second-named ports and movable radially of the rotor under the influence of centrifugal force to close said second-named ports and a spring opposing movement of said valve under the influence of centrifugal force, the grooves of the series being staggered with relation to one another and means to exhaust uid from the grooves.

l0. In'a rotary motor 4or the like, a stator having two circumferential series of spiral grooves arranged in parallel bands, the grooves of said series being oppositely spiraled, a rotor fitting the statorand having two groups of rotatable lobe piston elements the lobes of which coact with said grooves to block the same, and a supply port in the rotor traversing a circumferential band of the stator including those ends of the grooves of both series first engaged by the lobes of the associated piston elements, the piston elements associated with each series of grooves being two in number and being disposed in overlapping ngagement and means to exhaust uid from the grooves.

l1. In a rotary motor or the like, relatively rotatable elements, the outer element comprising a cylinder provided on its inner surface with a circumferential series of spiral grooves, means to introduce uid pressure to said grooves and exhaust fluid pressure therefrom, the inner element tting within the cylinder, rotatable pistons carried by said inner element and having lobes mesh ing with said grooves and blocking said grooves from end to end during their passage therethrough, the inner member having a slot in which the body portions of said pistons are disposed, the inner portions of said piston elements being in confronting 'overlapping relation, said piston elements rotating in opposite directions upon relative rotation of said inner and outer members.

l2. In a rotary motor or the like, a cylinder provided on its inner surface with a circumferential series of spiral grooves, a rotor in said cylinder, rotatable piston elements carried by the rotor and having lobes meshing with said grooves and blocking said grooves from end to end during their passage therethrough, the rotor having a slot in which the body portions of said piston elements are disposed, the inner portions of said piston elements being in confronting overlapping relation, the piston elements rotating in opposite directions as the rotor is rotated, the direction of rotation of the rotor and pistons being such that gyroscopic effects induced by said piston elements counteract the centrifugal effort of the piston elements.

13. In a rotary motor or the like, a cylinder provided on its inner surface with a circumferential series of spiral grooves, a rotor in said cyl inder, rotatable piston elements carried by the rotor and having lobes meshing with said grooves, the rotor having a slot in which the body portions of said piston elements are disposed, the inner portions of said piston elements being in confronting overlapping relation, pins upon which the piston elements are mounted, and fluid-pressure-operated means for-withdrawing said pins.

14. In a rotary motor or the like, a cylinder provided on its inner surface with a cireumferen tial series of spiral grooves, a rotor inI said cylin der, rotatable piston elements carried by the rotor and having lobes meshing with said grooves and blocking said grooves from end to end during their passage therethrough, the rotor having a slot in which the body portions of said piston elements are disposed, the inner portions of said piston elements beinfI in confronting overlapping relation, said cylinder being circumferentially divided at the substantial center of the series of grooves. 15. In a rotary motor or the like, a stator having two circumferential series of spiral grooves arranged in parallel bands, the grooves of said series being oppositely spiraled, a rotor fitting the stator and having two groups of rotatable lobed piston elements, the lobes of which coact with said grooves to block the same, and a supply port in the rotor traversing a circumferential b'and ofthe stator including those ends of the grooves of both series first engaged by the lobes of the associated' piston elements, the pistons of each series being two in number and being arranged within a slot formed in the rotor, the inner portions of the pistons of each series being in overlapping relation to one another and means to exhaust fluid from said grooves.

16. In a rotary motor or the like, a stator having two circumferential series of spiral grooves arranged in parallel bands, the grooves of said series being oppositely spiraled, a rotor fitting the stator and having two groups of rotatable lobed piston elements, the lobes of which coact with said grooves to block the same, and a supply port in the rotor traversing a circumferential band of the stator including those ends of the grooves of both series rst engaged by the lobes of the associated piston elements, the grooves of the series being staggered with relation to one another, the pistons of each series being two in number and being arranged within a slot formed in the rotor, the inner portions of the pistons of each series being in overlapping relation to one another and means to exhaust fiuid from said grooves.

17. The construction set forth in claim 1 wherein the direction of rotation of the rotor and of the piston elements is such that gyroscopic effort of the elements is opposed to the torque engendered by fluid pressure against the pistons.

18. The construction set forth in claim 1 wherein the direction of rotation of the rotor and of the piston elements is such that gyroscopic effort of the elements is opposed to the torque engendered by fluid pressure against the pistons, and gyroscopic effort preponderates to an extent such that the pistons grip one another at the point of separation whereby the pistons tend to swing about the point of separation as a pivot and thereby reduce the centrifugal effort of the blades.

19. In a rotary motor, aY stator having two circumferential series of spiral grooves arranged in parallel bands, the grooves of said series being oppositelyv spiraled, a rotor tting the stator and having two groups of rotatable lobed piston elements, the lobes of which co-act with said grooves to block the same, a supply port in the rotor for each series of grooves and traversing a circumferential band of the stator including the ends of the grooves rst engaged' by the lobes of the piston elements, a governor closing one of said supply ports at a predetermined rotor speed and means to exhaust iiuid from said grooves.

20. In a rotary motor or the like, a cylinder provided on its inner surface with a circumferential series of spiral grooves, a rotor in said cylinder, rotatable piston elements carried by the rotor and having lobes meshing with said grooves, the rotor having a slot inwhich the body portions of said piston elements are disposed. the inner portions of said piston elements being in confronting overlapping relation the piston elements having an extreme diameter greater than the diameter of the rotor and a mean diameter such that they may be completely conined within the slot of the rotor.

21. In a rotary motor, a stator having a circumferential series of spiral grooves formed therein, a rotor iitting the stator and having rotatable lobed piston elements the lobes of which co-act with said' grooves to block the same, a supply port. in the rotor traversing a 'circumferential band of the stator including those ends of the .grooves rst engaged by the lobes of the piston elements, a second supply port in said rotor traversng a band of said grooves immediately adjacent the band thereof traversed by the mst-named port, a valve'controlling said second-named port and movable under the inuence of centrifugal force to close the second-named port and a spring opposing movement of said valve under the iniiuence of centrifugal force and directly engaging the valve.

22. In a rotary motor, a stator having a circumferential series of spiral grooves formed therein. a rotor fitting the stator and having rotatable lobed piston elements the lobes of which co-act with said grooves to block the same, a supply port in the rotor traversing a circumferential band of the stator including the ends of the grooves first engaged by the lobes of the piston elements, a governor closing said supply port at a predetermined rotor speed, and means to exhaust fluid from said `grooves.

23. In a rotary motor or the like. a cylinder provided on its inner surface with a circumferential series of spiral cavities, a rotor in said cylinder, rotatable piston elements carried by the rotor and having lobes meshing with said cavities, the rotor having a slot in which the body portions of said piston elements are disposed, the inner portions of said piston elements being in confronting overlapping relation, there being a partition between said piston elements. the direction of rotation di the piston elements and the 'direction of vrotation of the rotor being such that the gyroscopic eEort of the pistons causes bind-A ing opposing the centrifugal effort thereof.

PAUL E. GOOD. 

